A circuit board structure includes a first dielectric layer, first and second inner circuit layers, a conductive connection layer, a second dielectric layer, two third dielectric layers, third and fourth inner circuit layers, two conductive through vias, first and second annular retaining walls, two fourth dielectric layers, first and second external circuit layers, and third and fourth annular retaining walls. The conductive through vias penetrate the third and second dielectric layers and electrically connect the third and fourth inner circuit layers. The first and second annular retaining walls surround the conductive through vias and electrically connect the third and first and the fourth and second inner circuit layers. The third and fourth annular retaining walls are respectively disposed in the fourth dielectric layers and electrically connect the first external circuit layer and the third inner circuit layer and the second external circuit layer and the fourth inner circuit layer.
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1. A circuit board structure, comprising:
a first dielectric layer, having a first surface and a second surface opposite to each other and an opening penetrating the first dielectric layer and connecting the first surface and the second surface;
a first inner circuit layer, disposed on the first surface of the first dielectric layer;
a second inner circuit layer, disposed on the second surface of the first dielectric layer;
a conductive connection layer, covering an inner wall of the opening of the first dielectric layer and connecting the first inner circuit layer and the second inner circuit layer;
a second dielectric layer, filling the opening of the first dielectric layer;
two third dielectric layers, respectively covering the first inner circuit layer, the second inner circuit layer, and the second dielectric layer;
a third inner circuit layer and a fourth inner circuit layer, respectively covering the third dielectric layers;
two conductive through vias, penetrating the third dielectric layers and the second dielectric layer, and electrically connecting the third inner circuit layer and the fourth inner circuit layer;
a first annular retaining wall and a second annular retaining wall, respectively disposed in the third dielectric layers, surrounding the conductive through vias, and electrically connecting the third inner circuit layer and the first inner circuit layer and the fourth inner circuit layer and the second inner circuit layer;
two fourth dielectric layers, respectively covering the third inner circuit layer and the fourth inner circuit layer;
a first external circuit layer and a second external circuit layer, respectively covering the fourth dielectric layers; and
a third annular retaining wall and a fourth annular retaining wall, respectively disposed in the fourth dielectric layers and electrically connecting the first external circuit layer and the third inner circuit layer and the second external circuit layer and the fourth inner circuit layer.
6. A circuit board structure, comprising:
two circuit board units, each of the circuit board units comprising:
a first dielectric layer, having a first surface and a second surface opposite to each other and an opening penetrating the first dielectric layer and connecting the first surface and the second surface;
a first inner circuit layer, disposed on the first surface of the first dielectric layer;
a second inner circuit layer, disposed on the second surface of the first dielectric layer;
a conductive connection layer, covering an inner wall of the opening of the first dielectric layer and connecting the first inner circuit layer and the second inner circuit layer;
a second dielectric layer, filling the opening of the first dielectric layer;
two third dielectric layers, respectively covering the first inner circuit layer, the second inner circuit layer, and the second dielectric layer;
a third inner circuit layer and a fourth inner circuit layer, respectively covering the third dielectric layers;
two conductive through vias, penetrating the third dielectric layers and the second dielectric layer, and electrically connecting the third inner circuit layer and the fourth inner circuit layer;
a first annular retaining wall and a second annular retaining wall, respectively disposed in the third dielectric layers, surrounding the conductive through vias, and electrically connecting the third inner circuit layer and the first inner circuit layer and the fourth inner circuit layer and the second inner circuit layer;
two fourth dielectric layers, respectively covering the third inner circuit layer and the fourth inner circuit layer;
a first external circuit layer and a second external circuit layer, respectively covering the fourth dielectric layers; and
a third annular retaining wall and a fourth annular retaining wall, respectively disposed in the fourth dielectric layers and electrically connecting the first external circuit layer and the third inner circuit layer and the second external circuit layer and the fourth inner circuit layer, wherein a part of at least one of the third annular retaining wall and the fourth annular retaining wall is disposed corresponding to the conductive through vias; and
a connection structural layer, comprising a connection layer and a plurality of conductive bonding portions, wherein the connection layer is located between the circuit board units and covers the first external circuit layer of each of the circuit board units, and the conductive bonding portions are connected to the first external circuit layer of each of the circuit board units, so that the circuit board units are docked together.
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10. The circuit board structure according to
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This application claims the priority benefit of U.S. Provisional Application No. 63/279,661, filed on Nov. 15, 2021 and Taiwan Application No. 111124282, filed on Jun. 29, 2022. The entirety of each of the above-mentioned patent applications is hereby incorporated by reference herein and made a part of this specification.
The disclosure relates to a substrate structure, and in particular to a circuit board structure.
In the existing circuit board, the design of the coaxial via requires one or more insulating layers for insulation between the inner conductor layer and the outer conductor layer. The manner of forming the insulating layer is achieved through build-up lamination. Therefore, there will be impedance mismatch at two ends of the coaxial via and an electromagnetic interference (EMI) shielding notch will appear, thereby affecting the integrity of high-frequency signals.
The disclosure provides a circuit board structure, which can effectively prevent energy loss and reduce noise interference to have preferred signal integrity.
A circuit board structure of the disclosure includes a first dielectric layer, a first inner circuit layer, a second inner circuit layer, a conductive connection layer, a second dielectric layer, two third dielectric layers, a third inner circuit layer, a fourth inner circuit layer, two conductive through vias, a first annular retaining wall, a second annular retaining wall, two fourth dielectric layers, a first external circuit layer, a second external circuit layer, a third annular retaining wall, and a fourth annular retaining wall. The first dielectric layer has a first surface and a second surface opposite to each other and an opening penetrating the first dielectric layer and connecting the first surface and the second surface. The first inner circuit layer is disposed on the first surface of the first dielectric layer. The second inner circuit layer is disposed on the second surface of the first dielectric layer. The conductive connection layer covers an inner wall of the opening of the first dielectric layer and connects the first inner circuit layer and the second inner circuit layer. The second dielectric layer fills the opening of the first dielectric layer. The third dielectric layer respectively covers the first inner circuit layer, the second inner circuit layer, and the second dielectric layer. The third inner circuit layer and the fourth inner circuit layer respectively cover the third dielectric layer. The conductive through vias penetrate the third dielectric layer and the second dielectric layer, and electrically connect the third inner circuit layer and the fourth inner circuit layer. The first annular retaining wall and the second annular retaining wall are respectively disposed in the third dielectric layer, surround the conductive through vias, and electrically connect the third inner circuit layer and the first inner circuit layer and the fourth inner circuit layer and the second inner circuit layer. The fourth dielectric layer respectively covers the third inner circuit layer and the fourth inner circuit layer. The first external circuit layer and the second external circuit layer respectively cover the fourth dielectric layer. The third annular retaining wall and the fourth annular retaining wall are respectively disposed in the fourth dielectric layer and electrically connect the first external circuit layer and the third inner circuit layer and the second external circuit layer and the fourth inner circuit layer.
A circuit board structure of the disclosure includes two circuit board units and a connection structural layer. Each circuit board unit includes a first inner circuit layer, a second inner circuit layer, a conductive connection layer, a second dielectric layer, two third dielectric layers, a third inner circuit layer, a fourth inner circuit layer, two conductive through vias, a first annular retaining wall, a second annular retaining wall, two fourth dielectric layers, a first external circuit layer, a second external circuit layer, a third annular retaining wall, and a fourth annular retaining wall. The first dielectric layer has a first surface and a second surface opposite to each other and an opening penetrating the first dielectric layer and connecting the first surface and the second surface. The first inner circuit layer is disposed on the first surface of the first dielectric layer. The second inner circuit layer is disposed on the second surface of the first dielectric layer. The conductive connection layer covers an inner wall of the opening of the first dielectric layer and connects the first inner circuit layer and the second inner circuit layer. The second dielectric layer fills the opening of the first dielectric layer. The third dielectric layer respectively covers the first inner circuit layer, the second inner circuit layer, and the second dielectric layer. The third inner circuit layer and the fourth inner circuit layer respectively cover the third dielectric layer. The conductive through vias penetrate the third dielectric layer and the second dielectric layer, and electrically connect the third inner circuit layer and the fourth inner circuit layer. The first annular retaining wall and the second annular retaining wall are respectively disposed in the third dielectric layer, surround the conductive through vias, and electrically connect the third inner circuit layer and the first inner circuit layer and the fourth inner circuit layer and the second inner circuit layer. The fourth dielectric layer respectively covers the third inner circuit layer and the fourth inner circuit layer. The first external circuit layer and the second external circuit layer respectively cover the fourth dielectric layer. The third annular retaining wall and the fourth annular retaining wall are respectively disposed in the fourth dielectric layer and electrically connect the first external circuit layer and the third inner circuit layer and the second external circuit layer and the fourth inner circuit layer. A part of at least one of the third annular retaining wall and the fourth annular retaining wall is disposed corresponding to the conductive through vias. The connection structural layer includes a connection layer and multiple conductive bonding portions. The connection layer is located between the circuit board units and covers the first external circuit layer of each circuit board unit, and the conductive bonding portions are connected to the first external circuit layer of each circuit board unit, so that the circuit board units are docked together.
Based on the above, in the design of the circuit board structure of the disclosure, the first annular retaining wall and the second annular retaining wall surround the conductive through vias and electrically connect the third inner circuit layer and the first inner circuit layer and the fourth inner circuit layer and the second inner circuit layer, and the third annular retaining wall and the fourth annular retaining wall electrically connect the first external circuit layer and the third inner circuit layer and the second external circuit layer and the fourth inner circuit layer. With such a design, the annular retaining walls present a closed boundary structure, which can reduce electromagnetic interference (EMI) and completely cover signals of the conductive through vias. Compared with the prior art in which single-row blind holes with gaps are disposed around the conductive through vias, the circuit board structure of the disclosure can also effectively prevent energy loss and reduce noise interference, so as to have preferred signal integrity.
In order for the features and advantages of the disclosure to be more comprehensible, the following specific embodiments are described in detail in conjunction with the drawings.
Please refer to
Specifically, in this embodiment, the first dielectric layer 110 has a first surface S1 and a second surface S2 opposite to each other and an opening H penetrating the first dielectric layer 110 and connecting the first surface S1 and the second surface S2. The first inner circuit layer 120 is disposed on the first surface S1 of the first dielectric layer 110. The second inner circuit layer 125 is disposed on the second surface S2 of the first dielectric layer 110. The conductive connection layer 127 covers an inner wall of the opening H of the first dielectric layer 110 and connects the first inner circuit layer 120 and the second inner circuit layer 125. The second dielectric layer 113 fills the opening H of the first dielectric layer 110 and aligns the first inner circuit layer 120 with the second inner circuit layer 125. Here, the first dielectric layer 110 may use a general dielectric material, wherein the dielectric constant of the first dielectric layer 110 may be lower than 5.0, and the dielectric loss (Df) of the first dielectric layer 110 may be lower than 0.02, so as to provide proper impedance matching. The dielectric constant of the second dielectric layer 113 may be lower than 5.0, and the dielectric loss (Df) of the second dielectric layer 113 is greater than 0 and less than 0.025, so as to provide proper insulation and impedance matching, and also reduce the dielectric loss.
Furthermore, the third dielectric layer 115 of this embodiment respectively covers the first inner circuit layer 120, the second inner circuit layer 125, and two opposite sides of the second dielectric layer 113. The third inner circuit layer 130 and the fourth inner circuit layer 140 respectively cover the third dielectric layer 115. The conductive through vias 150 penetrate the third dielectric layer 115 and the second dielectric layer 113, and electrically connect the third inner circuit layer 130 and the fourth inner circuit layer 140. More specifically, in this embodiment, each conductive through via 150 includes a through hole 152, a conductive material layer 154, and a hole filling material 156. The through hole 152 penetrates the third dielectric layer 115 and the second dielectric layer 113, and the conductive material layer 154 covers an inner wall of the through hole 152 and electrically connects the third inner circuit layer 130 and the fourth inner circuit layer 140. The hole filling material 156 fills the through hole 152, and the third inner circuit layer 130 and the fourth inner circuit layer 140 respectively cover an upper surface 157 and a lower surface 159 opposite to each other of the hole filling material 156.
Furthermore, the first annular retaining wall 160 and the second annular retaining wall 165 of this embodiment are respectively disposed in the third dielectric layer 115, surround the conductive through vias 150, and electrically connect the third inner circuit layer 130 and the first inner circuit layer 120 and the fourth inner circuit layer 140 and the second inner circuit layer 125. The fourth dielectric layer 117 respectively covers the third inner circuit layer 130 and the fourth inner circuit layer 140. The first external circuit layer 170 and the second external circuit layer 180 respectively cover the fourth dielectric layer 117. The third annular retaining wall 190 and the fourth annular retaining wall 195 are respectively disposed in the fourth dielectric layer 117 and electrically connect the first external circuit layer 170 and the third inner circuit layer 130 and the second external circuit layer 180 and the fourth inner circuit layer 140. Here, the third dielectric layer 115 and the fourth dielectric layer 117 may respectively be, for example, a photo imageable dielectric (PID) material, a pre-preg, or an Ajinomoto build-up film (ABF). The dielectric constants of the third dielectric layer 115 and the fourth dielectric layer 117 may be lower than 4.2, and the dielectric losses (Df) of the third dielectric layer 115 and the fourth dielectric layer 117 may be greater than 0 and less than 0.01.
In particular, in this embodiment, the third inner circuit layer 130, the conductive through vias 150, and the fourth inner circuit layer 140 define two signal paths L11, the first external circuit layer 170, the third annular retaining wall 190, the third inner circuit layer 130, the first annular retaining wall 160, the first inner circuit layer 120, the conductive connection layer 127, the second inner circuit layer 125, the second annular retaining wall 165, the fourth inner circuit layer 140, the fourth annular retaining wall 195, and the second external circuit layer 180 define a ground path L12, and the ground path L12 surrounds the signal paths L11.
Further, please refer to
In addition, please refer to
In short, in this embodiment, the signal paths L11 defined by the signal circuit 132, the conductive through vias 150, and the signal circuit 142 are surrounded and enclosed by the ground path L12 defined by the ground circuit 174, the third annular retaining wall 190, the ground circuit 134, the first annular retaining wall 160, the first inner circuit layer 120, the conductive connection layer 127, the second inner circuit layer 125, the second annular retaining wall 165, the ground circuit 144, the fourth annular retaining wall 195, and the second ground circuit 184. That is, the ground path L12 with good enclosure is disposed around the signal paths L11 that may transmit high-frequency high-speed signals such as 5G, so that a good high-frequency high-speed loop can be formed, and the circuit board structure 100 of this embodiment can have preferred signal integrity. Here, the high frequency refers to frequency greater than 1 GHz; and the high speed refers to data transmission speed greater than 100 Mbps.
Furthermore, since the first annular retaining wall 160, the second annular retaining wall 165, the third annular retaining wall 190, and the fourth annular retaining wall 195 present a closed boundary structure, signals of the conductive through vias 150. can be completely covered. Compared with the prior art in which single-row blind holes with gaps are disposed around the conductive through vias, the circuit board structure 100a of the embodiment can effectively prevent energy loss and reduce noise interference to have preferred signal integrity. In addition, the conductive through vias 150, the conductive connection layer 127, and the second dielectric layer 113 define a coaxial via, wherein the second dielectric layer 113 is located between the conductive through vias 150 and the conductive connection layer 127. Compared with the prior art in which the inner conductor layer and the outer conductor layer of the coaxial via are insulated by the build-up method of laminating the insulating layers, a manufacturing method of the circuit board structure 100a of this embodiment can avoid the issue of impedance mismatch that affects the integrity of high-frequency signals.
Please refer to
In this embodiment, the upper circuit board structure 100b is located at the first position P1 and the lower circuit board structure 100b is located at the first position P1, and when the circuit board structure 100b and the circuit board structure 100b are docked together, the signal circuit 142, the conductive through vias 150, the signal circuit 132, the third annular retaining wall 192 corresponding to the conductive through vias 150, the signal circuit 172, and the first conductive bonding portions 214 of the upper circuit board structure 100b, and the signal circuit 172, the third annular retaining wall 192 corresponding to the conductive through vias 150, the signal circuit 132, the conductive through vias 150, and the signal circuit 142 of the lower circuit board structure 100b define two signal paths L31. The ground circuit 184, the fourth annular retaining wall 195, the ground circuit 144, the second annular retaining wall 165, the second inner circuit layer 125, the conductive connection layer 127, the first inner circuit layer 120, the first annular retaining wall 160, the ground circuit 134, the third annular retaining wall 190, the ground circuit 174, and the second conductive bonding portions 216 of the upper circuit board structure 100b, and the ground circuit 174, the third annular retaining wall 190, the ground circuit 134, the first annular retaining wall 160, the first inner circuit layer 120, the conductive connection layer 127, the second inner circuit layer 125, the second annular retaining wall 165, the ground circuit 144, the fourth annular retaining wall 195, and the ground circuit 184 of the lower circuit board structure 100b define a ground path L32, and the ground path L32 surrounds the signal paths L31. Since the signal paths L31 are surrounded and enclosed by the ground path L32 in a closed manner, a good high-frequency high-speed loop can be formed.
When the upper circuit board structure 100c is located at the first position P1 and the lower circuit board structure 100b is located at the second position P2, and the circuit board structure 100c and the circuit board structure 100b are docked together, the signal circuit 182, the fourth annular retaining wall 197 disposed corresponding to the conductive through vias 150, the signal circuit 142, the conductive through vias 150, the signal circuit 132, the third annular retaining wall 192 disposed corresponding to the conductive through vias 150, the signal circuit 172, and the first conductive bonding portions 214 of the upper circuit board structure 100b, and the signal circuit 172, the third annular retaining wall 192 disposed corresponding to the conductive through vias 150, and the signal circuit 132 of the lower circuit board structure 100b define two signal paths L41. The ground circuit 184, the fourth annular retaining wall 195, the ground circuit 144, the second annular retaining wall 165, the second inner circuit layer 125, the conductive connection layer 127, the first inner circuit layer 120, the first annular retaining wall 160, the ground circuit 134, the third annular retaining wall 190, the ground circuit 174, and the second conductive bonding portions 216 of the upper circuit board structure 100b, and the ground circuit 174, the third annular retaining wall 190, the ground circuit 134, the first annular retaining wall 160, and the first inner circuit layer 120 of the lower circuit board structure 100b define a ground path L42 (that is, a first ground path), and the first ground path L42 surrounds the signal paths L41. Since the signal paths L41 are surrounded and enclosed by the ground path L42 in a closed manner, a good high-frequency high-speed loop can be formed.
In addition, the second inner circuit layer 125, the second annular retaining wall 165, the ground circuit 144, the fourth annular retaining wall 195, and the ground circuit 184 of the lower circuit board structure 100b define a ground path L43 (that is, a second ground path), and the ground path L43 surrounds and encloses the signal circuit 142 of the circuit board structure 100b in a closed manner, so a good high-frequency high-speed loop can be formed.
When the upper circuit board structure 100a is located at the second position P2 and the lower circuit board structure 100a is located at the second position P2, and the circuit board structure 100a and the circuit board structure 100a are docked together, the second inner circuit layer 125, the second annular retaining wall 165, the ground circuit 144, the fourth annular retaining wall 195, and the ground circuit 184 of the upper circuit board structure 100a define a ground path L51, and the ground path L51 surrounds and encloses the signal circuit 142 in a closed manner, so a good high-frequency high-speed loop can be formed.
Furthermore, the first inner circuit layer 120, the first annular retaining wall 160, the ground circuit 134, the third annular retaining wall 190, the ground circuit 174, the second conductive bonding portions 216, the ground circuit 174, the third annular retaining wall 190, the ground circuit 134, the first annular retaining wall 160, and the first inner circuit layer 120 of the upper circuit board structure 100a define a ground path L52, and the ground path L52 surrounds and encloses the signal circuit 132 in a closed manner, so a good high-frequency high-speed loop can be formed. In addition, the second inner circuit layer 125, the second annular retaining wall 165, the ground circuit 144, the fourth annular retaining wall 195, and the ground circuit 184 of the lower circuit board structure 100a define a ground path L51, and the ground path L51 surrounds and encloses the signal circuit 142 in a closed manner, so a good high-frequency high-speed loop can be formed.
It should be noted that the docking manners mentioned in the above embodiments are all docking the first external circuit layers of the two circuit board structures together. Of course, in other embodiments not shown, the docking manner may also be docking a first external circuit layer of one circuit board structure to a second external circuit layer of another circuit board structure; or docking second external circuit layers of two circuit board structures together, which all belong to the protection scope of the disclosure.
In summary, in the design of the circuit board structure of the disclosure, the first annular retaining wall and the second annular retaining wall surround the conductive through vias and electrically connect the third inner circuit layer and the first inner circuit layer and the fourth inner circuit layer and the second inner circuit layer, and the third annular retaining wall and the fourth annular retaining wall electrically connect the first external circuit layer and the third inner circuit layer and the second external circuit layer and the fourth inner circuit layer. With such a design, the annular retaining walls present a closed boundary structure, which can reduce electromagnetic interference (EMI) and completely cover signals of the conductive through vias. Compared with the prior art in which single-row blind holes with gaps are disposed around the conductive through vias, the circuit board structure of the disclosure can also effectively prevent energy loss and reduce noise interference, so as to have preferred signal integrity.
Although the disclosure has been disclosed in the above embodiments, the embodiments are not intended to limit the disclosure. Persons skilled in the art may make some changes and modifications without departing from the spirit and scope of the disclosure. Therefore, the protection scope of the disclosure shall be defined by the appended claims.
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